Bacterioplankton in the light of seasonality and environmental drivers

Bacterioplankton are keystone organisms in marine ecosystems. They are important for element cycles, by transforming dissolved organic carbon and other nutrients. Bacterioplankton community composition and productivity rates change in surface waters over spatial and temporal scales. Yet, many underl...

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Bibliographic Details
Main Author: Bunse, Carina
Format: Doctoral or Postdoctoral Thesis
Language:English
Published: Linnéuniversitetet, Institutionen för biologi och miljö (BOM) 2017
Subjects:
marine bacteria
marine microbiology
seasonal succession
ocean acidification
proteorhodopsin
photoheterotrophy
microbial time series
Environmental Sciences
Miljövetenskap
Oceanography
Hydrology and Water Resources
Oceanografi
hydrologi och vattenresurser
Microbiology
Mikrobiologi
Ocean acidification
Online Access:http://urn.kb.se/resolve?urn=urn:nbn:se:umu:diva-145242
id ftumeauniv:oai:DiVA.org:umu-145242
record_format openpolar
spelling ftumeauniv:oai:DiVA.org:umu-145242 2023-10-09T21:54:52+02:00 Bacterioplankton in the light of seasonality and environmental drivers Bunse, Carina 2017 application/pdf http://urn.kb.se/resolve?urn=urn:nbn:se:umu:diva-145242 eng eng Linnéuniversitetet, Institutionen för biologi och miljö (BOM) Växjö : Linnaeus University Press http://urn.kb.se/resolve?urn=urn:nbn:se:umu:diva-145242 urn:isbn:978-91-88761-03-3 urn:isbn:978-91-88761-02-6 info:eu-repo/semantics/openAccess marine bacteria marine microbiology seasonal succession ocean acidification proteorhodopsin photoheterotrophy microbial time series Environmental Sciences Miljövetenskap Oceanography Hydrology and Water Resources Oceanografi hydrologi och vattenresurser Microbiology Mikrobiologi Doctoral thesis, comprehensive summary info:eu-repo/semantics/doctoralThesis text 2017 ftumeauniv 2023-09-22T13:48:07Z Bacterioplankton are keystone organisms in marine ecosystems. They are important for element cycles, by transforming dissolved organic carbon and other nutrients. Bacterioplankton community composition and productivity rates change in surface waters over spatial and temporal scales. Yet, many underlying biological processes determining when, why and how bacterioplankton react to changes in environmental conditions are poorly understood. Here, I used experiments with model bacteria and natural assemblages as well as field studies to determine molecular, physiological and ecological responses allowing marine bacteria to adapt to their environment. Experiments with the flavobacterium Dokdonia sp. MED134 aimed to determine how the metabolism of bacteria is influenced by light and different organic matter. Under light exposure, Dokdonia sp. MED134 expressed proteorhodopsin and adjusted its metabolism to use resources more efficiently when growing with lower-quality organic matter. Similar expression patterns were found in oceanic datasets, implying a global importance of photoheterotrophic metabolisms for the ecology of bacterioplankton. Further, I investigated how the composition and physiology of bacterial assemblages are affected by elevated CO2 concentrations and inorganic nutrients. In a large-scale experiment, bacterioplankton could keep productivity and community structure unaltered by adapting the gene expression under CO2 stress. To maintain pH homeostasis, bacteria induced higher expression of genes related to respiration, membrane transport and light acquisition under low-nutrient conditions. Under high-nutrient conditions with phytoplankton blooms, such regulatory mechanisms were not necessary. These findings indicate that open ocean systems are more vulnerable to ocean acidification than coastal waters. Lastly, I used field studies to resolve how bacterioplankton is influenced by environmental changes, and how this leads to seasonal succession of marine bacteria. Using high frequency sampling over three ... Doctoral or Postdoctoral Thesis Ocean acidification Umeå University: Publications (DiVA)
institution Open Polar
collection Umeå University: Publications (DiVA)
op_collection_id ftumeauniv
language English
topic marine bacteria
marine microbiology
seasonal succession
ocean acidification
proteorhodopsin
photoheterotrophy
microbial time series
Environmental Sciences
Miljövetenskap
Oceanography
Hydrology and Water Resources
Oceanografi
hydrologi och vattenresurser
Microbiology
Mikrobiologi
spellingShingle marine bacteria
marine microbiology
seasonal succession
ocean acidification
proteorhodopsin
photoheterotrophy
microbial time series
Environmental Sciences
Miljövetenskap
Oceanography
Hydrology and Water Resources
Oceanografi
hydrologi och vattenresurser
Microbiology
Mikrobiologi
Bunse, Carina
Bacterioplankton in the light of seasonality and environmental drivers
topic_facet marine bacteria
marine microbiology
seasonal succession
ocean acidification
proteorhodopsin
photoheterotrophy
microbial time series
Environmental Sciences
Miljövetenskap
Oceanography
Hydrology and Water Resources
Oceanografi
hydrologi och vattenresurser
Microbiology
Mikrobiologi
description Bacterioplankton are keystone organisms in marine ecosystems. They are important for element cycles, by transforming dissolved organic carbon and other nutrients. Bacterioplankton community composition and productivity rates change in surface waters over spatial and temporal scales. Yet, many underlying biological processes determining when, why and how bacterioplankton react to changes in environmental conditions are poorly understood. Here, I used experiments with model bacteria and natural assemblages as well as field studies to determine molecular, physiological and ecological responses allowing marine bacteria to adapt to their environment. Experiments with the flavobacterium Dokdonia sp. MED134 aimed to determine how the metabolism of bacteria is influenced by light and different organic matter. Under light exposure, Dokdonia sp. MED134 expressed proteorhodopsin and adjusted its metabolism to use resources more efficiently when growing with lower-quality organic matter. Similar expression patterns were found in oceanic datasets, implying a global importance of photoheterotrophic metabolisms for the ecology of bacterioplankton. Further, I investigated how the composition and physiology of bacterial assemblages are affected by elevated CO2 concentrations and inorganic nutrients. In a large-scale experiment, bacterioplankton could keep productivity and community structure unaltered by adapting the gene expression under CO2 stress. To maintain pH homeostasis, bacteria induced higher expression of genes related to respiration, membrane transport and light acquisition under low-nutrient conditions. Under high-nutrient conditions with phytoplankton blooms, such regulatory mechanisms were not necessary. These findings indicate that open ocean systems are more vulnerable to ocean acidification than coastal waters. Lastly, I used field studies to resolve how bacterioplankton is influenced by environmental changes, and how this leads to seasonal succession of marine bacteria. Using high frequency sampling over three ...
format Doctoral or Postdoctoral Thesis
author Bunse, Carina
author_facet Bunse, Carina
author_sort Bunse, Carina
title Bacterioplankton in the light of seasonality and environmental drivers
title_short Bacterioplankton in the light of seasonality and environmental drivers
title_full Bacterioplankton in the light of seasonality and environmental drivers
title_fullStr Bacterioplankton in the light of seasonality and environmental drivers
title_full_unstemmed Bacterioplankton in the light of seasonality and environmental drivers
title_sort bacterioplankton in the light of seasonality and environmental drivers
publisher Linnéuniversitetet, Institutionen för biologi och miljö (BOM)
publishDate 2017
url http://urn.kb.se/resolve?urn=urn:nbn:se:umu:diva-145242
genre Ocean acidification
genre_facet Ocean acidification
op_relation http://urn.kb.se/resolve?urn=urn:nbn:se:umu:diva-145242
urn:isbn:978-91-88761-03-3
urn:isbn:978-91-88761-02-6
op_rights info:eu-repo/semantics/openAccess
_version_ 1779318599710670848

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